src/third_party/mozjs-45/intl/icu/source/common/umutex.cpp - cobalt - Git at Google

 /*
 ******************************************************************************
 *
 *   Copyright (C) 1997-2015, International Business Machines
 *   Corporation and others.  All Rights Reserved.
 *
 ******************************************************************************
 *
 * File umutex.cpp
 *
 * Modification History:
 *
 *   Date        Name        Description
 *   04/02/97    aliu        Creation.
 *   04/07/99    srl         updated
 *   05/13/99    stephen     Changed to umutex (from cmutex).
 *   11/22/99    aliu        Make non-global mutex autoinitialize [j151]
 ******************************************************************************
 */

 #include "umutex.h"

 #include "unicode/utypes.h"
 #include "uassert.h"
 #include "cmemory.h"


 // The ICU global mutex. Used when ICU implementation code passes NULL for the mutex pointer.
 static UMutex   globalMutex = U_MUTEX_INITIALIZER;

 /*
  * ICU Mutex wrappers.  Wrap operating system mutexes, giving the rest of ICU a
  * platform independent set of mutex operations.  For internal ICU use only.
  */

 #if defined(U_USER_MUTEX_CPP)
 // Build time user mutex hook: #include "U_USER_MUTEX_CPP"
 #include U_MUTEX_XSTR(U_USER_MUTEX_CPP)

 #elif U_PLATFORM_HAS_WIN32_API

 //-------------------------------------------------------------------------------------------
 //
 //    Windows Specific Definitions
 //
 //        Note: Cygwin (and possibly others) have both WIN32 and POSIX.
 //              Prefer Win32 in these cases.  (Win32 comes ahead in the #if chain)
 //
 //-------------------------------------------------------------------------------------------

 #if defined U_NO_PLATFORM_ATOMICS
 #error ICU on Win32 requires support for low level atomic operations.
 // Visual Studio, gcc, clang are OK. Shouldn't get here.
 #endif


 // This function is called when a test of a UInitOnce::fState reveals that
 //   initialization has not completed, that we either need to call the
 //   function on this thread, or wait for some other thread to complete.
 //
 // The actual call to the init function is made inline by template code
 //   that knows the C++ types involved. This function returns TRUE if
 //   the caller needs to call the Init function.
 //

 U_NAMESPACE_BEGIN

 U_COMMON_API UBool U_EXPORT2 umtx_initImplPreInit(UInitOnce &uio) {
     for (;;) {
         int32_t previousState = InterlockedCompareExchange(
 #if (U_PLATFORM == U_PF_MINGW) || (U_PLATFORM == U_PF_CYGWIN) || defined(__clang__)
            (LONG volatile *) // this is the type given in the API doc for this function.
 #endif
             &uio.fState,  //  Destination
             1,            //  Exchange Value
             0);           //  Compare value

         if (previousState == 0) {
             return true;   // Caller will next call the init function.
                            // Current state == 1.
         } else if (previousState == 2) {
             // Another thread already completed the initialization.
             //   We can simply return FALSE, indicating no
             //   further action is needed by the caller.
             return FALSE;
         } else {
             // Another thread is currently running the initialization.
             // Wait until it completes.
             do {
                 Sleep(1);
                 previousState = umtx_loadAcquire(uio.fState);
             } while (previousState == 1);
         }
     }
 }

 // This function is called by the thread that ran an initialization function,
 // just after completing the function.

 U_COMMON_API void U_EXPORT2 umtx_initImplPostInit(UInitOnce &uio) {
     umtx_storeRelease(uio.fState, 2);
 }

 U_NAMESPACE_END

 static void winMutexInit(CRITICAL_SECTION *cs) {
     InitializeCriticalSection(cs);
     return;
 }

 U_CAPI void  U_EXPORT2
 umtx_lock(UMutex *mutex) {
     if (mutex == NULL) {
         mutex = &globalMutex;
     }
     CRITICAL_SECTION *cs = &mutex->fCS;
     umtx_initOnce(mutex->fInitOnce, winMutexInit, cs);
     EnterCriticalSection(cs);
 }

 U_CAPI void  U_EXPORT2
 umtx_unlock(UMutex* mutex)
 {
     if (mutex == NULL) {
         mutex = &globalMutex;
     }
     LeaveCriticalSection(&mutex->fCS);
 }


 U_CAPI void U_EXPORT2
 umtx_condBroadcast(UConditionVar *condition) {
     // We require that the associated mutex be held by the caller,
     //  so access to fWaitCount is protected and safe. No other thread can
     //  call condWait() while we are here.
     if (condition->fWaitCount == 0) {
         return;
     }
     ResetEvent(condition->fExitGate);
     SetEvent(condition->fEntryGate);
 }

 U_CAPI void U_EXPORT2
 umtx_condSignal(UConditionVar *condition) {
     // Function not implemented. There is no immediate requirement from ICU to have it.
     // Once ICU drops support for Windows XP and Server 2003, ICU Condition Variables will be
     // changed to be thin wrappers on native Windows CONDITION_VARIABLEs, and this function
     // becomes trivial to provide.
     U_ASSERT(FALSE);
 }

 U_CAPI void U_EXPORT2
 umtx_condWait(UConditionVar *condition, UMutex *mutex) {
     if (condition->fEntryGate == NULL) {
         // Note: because the associated mutex must be locked when calling
         //       wait, we know that there can not be multiple threads
         //       running here with the same condition variable.
         //       Meaning that lazy initialization is safe.
         U_ASSERT(condition->fExitGate == NULL);
         condition->fEntryGate = CreateEvent(NULL,   // Security Attributes
                                             TRUE,   // Manual Reset
                                             FALSE,  // Initially reset
                                             NULL);  // Name.
         U_ASSERT(condition->fEntryGate != NULL);
         condition->fExitGate = CreateEvent(NULL, TRUE, TRUE, NULL);
         U_ASSERT(condition->fExitGate != NULL);
     }

     condition->fWaitCount++;
     umtx_unlock(mutex);
     WaitForSingleObject(condition->fEntryGate, INFINITE);
     umtx_lock(mutex);
     condition->fWaitCount--;
     if (condition->fWaitCount == 0) {
         // All threads that were waiting at the entry gate have woken up
         // and moved through. Shut the entry gate and open the exit gate.
         ResetEvent(condition->fEntryGate);
         SetEvent(condition->fExitGate);
     } else {
         umtx_unlock(mutex);
         WaitForSingleObject(condition->fExitGate, INFINITE);
         umtx_lock(mutex);
     }
 }


 #elif U_PLATFORM_IMPLEMENTS_POSIX

 //-------------------------------------------------------------------------------------------
 //
 //  POSIX specific definitions
 //
 //-------------------------------------------------------------------------------------------

 # include <pthread.h>

 // Each UMutex consists of a pthread_mutex_t.
 // All are statically initialized and ready for use.
 // There is no runtime mutex initialization code needed.

 U_CAPI void  U_EXPORT2
 umtx_lock(UMutex *mutex) {
     if (mutex == NULL) {
         mutex = &globalMutex;
     }
     int sysErr = pthread_mutex_lock(&mutex->fMutex);
     (void)sysErr;   // Suppress unused variable warnings.
     U_ASSERT(sysErr == 0);
 }


 U_CAPI void  U_EXPORT2
 umtx_unlock(UMutex* mutex)
 {
     if (mutex == NULL) {
         mutex = &globalMutex;
     }
     int sysErr = pthread_mutex_unlock(&mutex->fMutex);
     (void)sysErr;   // Suppress unused variable warnings.
     U_ASSERT(sysErr == 0);
 }


 U_CAPI void U_EXPORT2
 umtx_condWait(UConditionVar *cond, UMutex *mutex) {
     if (mutex == NULL) {
         mutex = &globalMutex;
     }
     int sysErr = pthread_cond_wait(&cond->fCondition, &mutex->fMutex);
     (void)sysErr;
     U_ASSERT(sysErr == 0);
 }

 U_CAPI void U_EXPORT2
 umtx_condBroadcast(UConditionVar *cond) {
     int sysErr = pthread_cond_broadcast(&cond->fCondition);
     (void)sysErr;
     U_ASSERT(sysErr == 0);
 }

 U_CAPI void U_EXPORT2
 umtx_condSignal(UConditionVar *cond) {
     int sysErr = pthread_cond_signal(&cond->fCondition);
     (void)sysErr;
     U_ASSERT(sysErr == 0);
 }


 U_NAMESPACE_BEGIN

 static pthread_mutex_t initMutex = PTHREAD_MUTEX_INITIALIZER;
 static pthread_cond_t initCondition = PTHREAD_COND_INITIALIZER;


 // This function is called when a test of a UInitOnce::fState reveals that
 //   initialization has not completed, that we either need to call the
 //   function on this thread, or wait for some other thread to complete.
 //
 // The actual call to the init function is made inline by template code
 //   that knows the C++ types involved. This function returns TRUE if
 //   the caller needs to call the Init function.
 //
 U_COMMON_API UBool U_EXPORT2
 umtx_initImplPreInit(UInitOnce &uio) {
     pthread_mutex_lock(&initMutex);
     int32_t state = uio.fState;
     if (state == 0) {
         umtx_storeRelease(uio.fState, 1);
         pthread_mutex_unlock(&initMutex);
         return TRUE;   // Caller will next call the init function.
     } else {
         while (uio.fState == 1) {
             // Another thread is currently running the initialization.
             // Wait until it completes.
             pthread_cond_wait(&initCondition, &initMutex);
         }
         pthread_mutex_unlock(&initMutex);
         U_ASSERT(uio.fState == 2);
         return FALSE;
     }
 }


 // This function is called by the thread that ran an initialization function,
 // just after completing the function.
 //   Some threads may be waiting on the condition, requiring the broadcast wakeup.
 //   Some threads may be racing to test the fState variable outside of the mutex,
 //   requiring the use of store/release when changing its value.

 U_COMMON_API void U_EXPORT2
 umtx_initImplPostInit(UInitOnce &uio) {
     pthread_mutex_lock(&initMutex);
     umtx_storeRelease(uio.fState, 2);
     pthread_cond_broadcast(&initCondition);
     pthread_mutex_unlock(&initMutex);
 }

 U_NAMESPACE_END

 // End of POSIX specific umutex implementation.

 #else  // Platform #define chain.

 #error Unknown Platform

 #endif  // Platform #define chain.


 //-------------------------------------------------------------------------------
 //
 //   Atomic Operations, out-of-line versions.
 //                      These are conditional, only defined if better versions
 //                      were not available for the platform.
 //
 //                      These versions are platform neutral.
 //
 //--------------------------------------------------------------------------------

 #if defined U_NO_PLATFORM_ATOMICS
 static UMutex   gIncDecMutex = U_MUTEX_INITIALIZER;

 U_NAMESPACE_BEGIN

 U_COMMON_API int32_t U_EXPORT2
 umtx_atomic_inc(u_atomic_int32_t *p)  {
     int32_t retVal;
     umtx_lock(&gIncDecMutex);
     retVal = ++(*p);
     umtx_unlock(&gIncDecMutex);
     return retVal;
 }


 U_COMMON_API int32_t U_EXPORT2
 umtx_atomic_dec(u_atomic_int32_t *p) {
     int32_t retVal;
     umtx_lock(&gIncDecMutex);
     retVal = --(*p);
     umtx_unlock(&gIncDecMutex);
     return retVal;
 }

 U_COMMON_API int32_t U_EXPORT2
 umtx_loadAcquire(u_atomic_int32_t &var) {
     umtx_lock(&gIncDecMutex);
     int32_t val = var;
     umtx_unlock(&gIncDecMutex);
     return val;
 }

 U_COMMON_API void U_EXPORT2
 umtx_storeRelease(u_atomic_int32_t &var, int32_t val) {
     umtx_lock(&gIncDecMutex);
     var = val;
     umtx_unlock(&gIncDecMutex);
 }

 U_NAMESPACE_END
 #endif

 //--------------------------------------------------------------------------
 //
 //  Deprecated functions for setting user mutexes.
 //
 //--------------------------------------------------------------------------

 U_DEPRECATED void U_EXPORT2
 u_setMutexFunctions(const void * /*context */, UMtxInitFn *, UMtxFn *,
                     UMtxFn *,  UMtxFn *, UErrorCode *status) {
     if (U_SUCCESS(*status)) {
         *status = U_UNSUPPORTED_ERROR;
     }
     return;
 }


 U_DEPRECATED void U_EXPORT2
 u_setAtomicIncDecFunctions(const void * /*context */, UMtxAtomicFn *, UMtxAtomicFn *,
                            UErrorCode *status) {
     if (U_SUCCESS(*status)) {
         *status = U_UNSUPPORTED_ERROR;
     }
     return;
 }
	/*
	******************************************************************************
	*
	* Copyright (C) 1997-2015, International Business Machines
	* Corporation and others. All Rights Reserved.
	*
	******************************************************************************
	*
	* File umutex.cpp
	*
	* Modification History:
	*
	* Date Name Description
	* 04/02/97 aliu Creation.
	* 04/07/99 srl updated
	* 05/13/99 stephen Changed to umutex (from cmutex).
	* 11/22/99 aliu Make non-global mutex autoinitialize [j151]
	******************************************************************************
	*/

	#include "umutex.h"

	#include "unicode/utypes.h"
	#include "uassert.h"
	#include "cmemory.h"


	// The ICU global mutex. Used when ICU implementation code passes NULL for the mutex pointer.
	static UMutex globalMutex = U_MUTEX_INITIALIZER;

	/*
	* ICU Mutex wrappers. Wrap operating system mutexes, giving the rest of ICU a
	* platform independent set of mutex operations. For internal ICU use only.
	*/

	#if defined(U_USER_MUTEX_CPP)
	// Build time user mutex hook: #include "U_USER_MUTEX_CPP"
	#include U_MUTEX_XSTR(U_USER_MUTEX_CPP)

	#elif U_PLATFORM_HAS_WIN32_API

	//-------------------------------------------------------------------------------------------
	//
	// Windows Specific Definitions
	//
	// Note: Cygwin (and possibly others) have both WIN32 and POSIX.
	// Prefer Win32 in these cases. (Win32 comes ahead in the #if chain)
	//
	//-------------------------------------------------------------------------------------------

	#if defined U_NO_PLATFORM_ATOMICS
	#error ICU on Win32 requires support for low level atomic operations.
	// Visual Studio, gcc, clang are OK. Shouldn't get here.
	#endif


	// This function is called when a test of a UInitOnce::fState reveals that
	// initialization has not completed, that we either need to call the
	// function on this thread, or wait for some other thread to complete.
	//
	// The actual call to the init function is made inline by template code
	// that knows the C++ types involved. This function returns TRUE if
	// the caller needs to call the Init function.
	//

	U_NAMESPACE_BEGIN

	U_COMMON_API UBool U_EXPORT2 umtx_initImplPreInit(UInitOnce &uio) {
	for (;;) {
	int32_t previousState = InterlockedCompareExchange(
	#if (U_PLATFORM == U_PF_MINGW) \|\| (U_PLATFORM == U_PF_CYGWIN) \|\| defined(__clang__)
	(LONG volatile *) // this is the type given in the API doc for this function.
	#endif
	&uio.fState, // Destination
	1, // Exchange Value
	0); // Compare value

	if (previousState == 0) {
	return true; // Caller will next call the init function.
	// Current state == 1.
	} else if (previousState == 2) {
	// Another thread already completed the initialization.
	// We can simply return FALSE, indicating no
	// further action is needed by the caller.
	return FALSE;
	} else {
	// Another thread is currently running the initialization.
	// Wait until it completes.
	do {
	Sleep(1);
	previousState = umtx_loadAcquire(uio.fState);
	} while (previousState == 1);
	}
	}
	}

	// This function is called by the thread that ran an initialization function,
	// just after completing the function.

	U_COMMON_API void U_EXPORT2 umtx_initImplPostInit(UInitOnce &uio) {
	umtx_storeRelease(uio.fState, 2);
	}

	U_NAMESPACE_END

	static void winMutexInit(CRITICAL_SECTION *cs) {
	InitializeCriticalSection(cs);
	return;
	}

	U_CAPI void U_EXPORT2
	umtx_lock(UMutex *mutex) {
	if (mutex == NULL) {
	mutex = &globalMutex;
	}
	CRITICAL_SECTION *cs = &mutex->fCS;
	umtx_initOnce(mutex->fInitOnce, winMutexInit, cs);
	EnterCriticalSection(cs);
	}

	U_CAPI void U_EXPORT2
	umtx_unlock(UMutex* mutex)
	{
	if (mutex == NULL) {
	mutex = &globalMutex;
	}
	LeaveCriticalSection(&mutex->fCS);
	}


	U_CAPI void U_EXPORT2
	umtx_condBroadcast(UConditionVar *condition) {
	// We require that the associated mutex be held by the caller,
	// so access to fWaitCount is protected and safe. No other thread can
	// call condWait() while we are here.
	if (condition->fWaitCount == 0) {
	return;
	}
	ResetEvent(condition->fExitGate);
	SetEvent(condition->fEntryGate);
	}

	U_CAPI void U_EXPORT2
	umtx_condSignal(UConditionVar *condition) {
	// Function not implemented. There is no immediate requirement from ICU to have it.
	// Once ICU drops support for Windows XP and Server 2003, ICU Condition Variables will be
	// changed to be thin wrappers on native Windows CONDITION_VARIABLEs, and this function
	// becomes trivial to provide.
	U_ASSERT(FALSE);
	}

	U_CAPI void U_EXPORT2
	umtx_condWait(UConditionVar condition, UMutex mutex) {
	if (condition->fEntryGate == NULL) {
	// Note: because the associated mutex must be locked when calling
	// wait, we know that there can not be multiple threads
	// running here with the same condition variable.
	// Meaning that lazy initialization is safe.
	U_ASSERT(condition->fExitGate == NULL);
	condition->fEntryGate = CreateEvent(NULL, // Security Attributes
	TRUE, // Manual Reset
	FALSE, // Initially reset
	NULL); // Name.
	U_ASSERT(condition->fEntryGate != NULL);
	condition->fExitGate = CreateEvent(NULL, TRUE, TRUE, NULL);
	U_ASSERT(condition->fExitGate != NULL);
	}

	condition->fWaitCount++;
	umtx_unlock(mutex);
	WaitForSingleObject(condition->fEntryGate, INFINITE);
	umtx_lock(mutex);
	condition->fWaitCount--;
	if (condition->fWaitCount == 0) {
	// All threads that were waiting at the entry gate have woken up
	// and moved through. Shut the entry gate and open the exit gate.
	ResetEvent(condition->fEntryGate);
	SetEvent(condition->fExitGate);
	} else {
	umtx_unlock(mutex);
	WaitForSingleObject(condition->fExitGate, INFINITE);
	umtx_lock(mutex);
	}
	}


	#elif U_PLATFORM_IMPLEMENTS_POSIX

	//-------------------------------------------------------------------------------------------
	//
	// POSIX specific definitions
	//
	//-------------------------------------------------------------------------------------------

	# include <pthread.h>

	// Each UMutex consists of a pthread_mutex_t.
	// All are statically initialized and ready for use.
	// There is no runtime mutex initialization code needed.

	U_CAPI void U_EXPORT2
	umtx_lock(UMutex *mutex) {
	if (mutex == NULL) {
	mutex = &globalMutex;
	}
	int sysErr = pthread_mutex_lock(&mutex->fMutex);
	(void)sysErr; // Suppress unused variable warnings.
	U_ASSERT(sysErr == 0);
	}


	U_CAPI void U_EXPORT2
	umtx_unlock(UMutex* mutex)
	{
	if (mutex == NULL) {
	mutex = &globalMutex;
	}
	int sysErr = pthread_mutex_unlock(&mutex->fMutex);
	(void)sysErr; // Suppress unused variable warnings.
	U_ASSERT(sysErr == 0);
	}


	U_CAPI void U_EXPORT2
	umtx_condWait(UConditionVar cond, UMutex mutex) {
	if (mutex == NULL) {
	mutex = &globalMutex;
	}
	int sysErr = pthread_cond_wait(&cond->fCondition, &mutex->fMutex);
	(void)sysErr;
	U_ASSERT(sysErr == 0);
	}

	U_CAPI void U_EXPORT2
	umtx_condBroadcast(UConditionVar *cond) {
	int sysErr = pthread_cond_broadcast(&cond->fCondition);
	(void)sysErr;
	U_ASSERT(sysErr == 0);
	}

	U_CAPI void U_EXPORT2
	umtx_condSignal(UConditionVar *cond) {
	int sysErr = pthread_cond_signal(&cond->fCondition);
	(void)sysErr;
	U_ASSERT(sysErr == 0);
	}



	U_NAMESPACE_BEGIN

	static pthread_mutex_t initMutex = PTHREAD_MUTEX_INITIALIZER;
	static pthread_cond_t initCondition = PTHREAD_COND_INITIALIZER;


	// This function is called when a test of a UInitOnce::fState reveals that
	// initialization has not completed, that we either need to call the
	// function on this thread, or wait for some other thread to complete.
	//
	// The actual call to the init function is made inline by template code
	// that knows the C++ types involved. This function returns TRUE if
	// the caller needs to call the Init function.
	//
	U_COMMON_API UBool U_EXPORT2
	umtx_initImplPreInit(UInitOnce &uio) {
	pthread_mutex_lock(&initMutex);
	int32_t state = uio.fState;
	if (state == 0) {
	umtx_storeRelease(uio.fState, 1);
	pthread_mutex_unlock(&initMutex);
	return TRUE; // Caller will next call the init function.
	} else {
	while (uio.fState == 1) {
	// Another thread is currently running the initialization.
	// Wait until it completes.
	pthread_cond_wait(&initCondition, &initMutex);
	}
	pthread_mutex_unlock(&initMutex);
	U_ASSERT(uio.fState == 2);
	return FALSE;
	}
	}



	// This function is called by the thread that ran an initialization function,
	// just after completing the function.
	// Some threads may be waiting on the condition, requiring the broadcast wakeup.
	// Some threads may be racing to test the fState variable outside of the mutex,
	// requiring the use of store/release when changing its value.

	U_COMMON_API void U_EXPORT2
	umtx_initImplPostInit(UInitOnce &uio) {
	pthread_mutex_lock(&initMutex);
	umtx_storeRelease(uio.fState, 2);
	pthread_cond_broadcast(&initCondition);
	pthread_mutex_unlock(&initMutex);
	}

	U_NAMESPACE_END

	// End of POSIX specific umutex implementation.

	#else // Platform #define chain.

	#error Unknown Platform

	#endif // Platform #define chain.


	//-------------------------------------------------------------------------------
	//
	// Atomic Operations, out-of-line versions.
	// These are conditional, only defined if better versions
	// were not available for the platform.
	//
	// These versions are platform neutral.
	//
	//--------------------------------------------------------------------------------

	#if defined U_NO_PLATFORM_ATOMICS
	static UMutex gIncDecMutex = U_MUTEX_INITIALIZER;

	U_NAMESPACE_BEGIN

	U_COMMON_API int32_t U_EXPORT2
	umtx_atomic_inc(u_atomic_int32_t *p) {
	int32_t retVal;
	umtx_lock(&gIncDecMutex);
	retVal = ++(*p);
	umtx_unlock(&gIncDecMutex);
	return retVal;
	}


	U_COMMON_API int32_t U_EXPORT2
	umtx_atomic_dec(u_atomic_int32_t *p) {
	int32_t retVal;
	umtx_lock(&gIncDecMutex);
	retVal = --(*p);
	umtx_unlock(&gIncDecMutex);
	return retVal;
	}

	U_COMMON_API int32_t U_EXPORT2
	umtx_loadAcquire(u_atomic_int32_t &var) {
	umtx_lock(&gIncDecMutex);
	int32_t val = var;
	umtx_unlock(&gIncDecMutex);
	return val;
	}

	U_COMMON_API void U_EXPORT2
	umtx_storeRelease(u_atomic_int32_t &var, int32_t val) {
	umtx_lock(&gIncDecMutex);
	var = val;
	umtx_unlock(&gIncDecMutex);
	}

	U_NAMESPACE_END
	#endif

	//--------------------------------------------------------------------------
	//
	// Deprecated functions for setting user mutexes.
	//
	//--------------------------------------------------------------------------

	U_DEPRECATED void U_EXPORT2
	u_setMutexFunctions(const void * /context /, UMtxInitFn , UMtxFn ,
	UMtxFn , UMtxFn , UErrorCode *status) {
	if (U_SUCCESS(*status)) {
	*status = U_UNSUPPORTED_ERROR;
	}
	return;
	}



	U_DEPRECATED void U_EXPORT2
	u_setAtomicIncDecFunctions(const void * /context /, UMtxAtomicFn , UMtxAtomicFn ,
	UErrorCode *status) {
	if (U_SUCCESS(*status)) {
	*status = U_UNSUPPORTED_ERROR;
	}
	return;
	}